KR102247905B1 - Leak detection apparatus with heating function - Google Patents

Abstract

The present invention relates to a leak detection device having a heat generating function, and in particular, in a device that detects leakage by attaching directly to a place (wall, pipe, facility, etc.) where leakage occurs in a tape method, the internal heating function is added to It relates to a leakage detection device having a heat generating function to prevent the occurrence of freezing waves due to freezing of the fluid flowing in the air.
To this end, the present invention is a base film layer formed in the form of a tape; A pair of sensing lines formed long in a longitudinal direction on an upper surface of the base film layer; A heating material formed at a side of the sensing line in a lengthwise direction of the base film layer; And a power line that is formed long in both directions of the heating material and is in contact with the heating material to supply power for heat generation of the heating material.

Description

Leak detection apparatus with heating function

The present invention relates to a leak detection device having a heat generating function, and in particular, in a device that detects leakage by attaching directly to a place (wall, pipe, facility, etc.) where leakage occurs in a tape method, the internal heating function is added to It relates to a leakage detection device having a heat generating function to prevent the occurrence of freezing waves due to freezing of the fluid flowing in the air.

The present applicant has already proposed a'leak detection device having a heating function' in Registration Patent No. 10-1200918.

The'leak detection device having a heating function' according to the prior art includes a base film layer 10 formed in the form of a tape as shown in FIG. 1; A conductive line 30 in which a plurality of resistive conductive lines 31 and 32 are formed side by side on an upper surface of the base film layer 10; It is laminated on top of the base film layer 10 to protect the base film layer 10, and a plurality of holes 41 are formed corresponding to positions corresponding to the conductive lines 31 and 32 of the conductive line 30. The formed upper protective film layer 40; And a controller for alternately applying a sensing signal for detecting a leak and power for heating to the conductive lines 31, 32, 33, and 34 constituting the conductive line 30.

The base film layer 10 is a layer on which the conductive line 30 is formed, and PET, PE, PTFE, PVC or other Teflon-based It is formed of a material.

The conductive line 30 is a layer on which a plurality of resistive conductive lines 31 and 32 are formed, and is disposed in a parallel strip shape while being spaced apart from each other in the longitudinal direction on the upper surface of the base film layer 10.

These conductive lines 31 and 32 are formed by a printing method using a silver compound. At this time, the ends of the first conductive line 31 and the second conductive line 32 are connected to each other so that they are electrically conductive. It is composed.

The base film layer 10 and the upper protective film layer 40 are combined by ultrasonic or thermal fusion, and then, the adhesive layer 20 in the form of a double-sided tape is bonded to the lower portion of the base film layer 10.

The ends of the conductive lines 31 and 32 are connected to a controller to receive a sensing signal for detecting a leak and power for heating.

The upper protective film layer 40 is a layer to protect the conductive line 30 formed on the base film layer 10 from external stimuli, and is formed of PET, PE, PVC, or Teflon-based material, and is a first conductive layer. Holes 41 are formed at regular intervals corresponding to the positions where the line 31 and the second conductive line 32 are formed, so that when a leak occurs, a leak is introduced through the hole 41 and the first conductive line 31 and the second conductive line 32 are formed. The second conductive line 32 is allowed to conduct.

Therefore, when a leak flows through the hole 41 of the upper protective film layer 40, since the first conductive line 31 and the second conductive line 32 are connected by the leak, the change in resistance value is prevented. A remote controller is input and it is possible to check whether a leak has occurred.

At this time, a pulse type detection signal is applied to the first conductive line 31 and the second conductive line 32, and when no detection signal is applied, the resistance of the conductive lines 31 and 32 is applied by applying power for heating. Heat is generated by this.

For this reason, when it is installed outside a pipe where freezing is likely to occur, it is possible to detect a leakage while preventing the freezing of the fluid.

However, such a conventional leak detection device applies power for heating through a conductive line for detecting a leak, but the resistance value of the conductive line is not so large, so the amount of heat generated is very small. There was a problem that could not be solved.

It is an object of the present invention to provide a leak detection device having a heating function in which a heating material for heat generation is separately provided in the tape-type leakage detection device as described above so as to detect leakage at the same time as efficient heat generation.

A leak detection device having a heat generating function according to an aspect of the present invention for achieving the above object,
A base film layer formed in the form of a tape;
A sensing line formed long in a longitudinal direction on an upper surface of the base film layer;
A heating material formed on an upper surface of the base film layer to have a predetermined width at one side of the sensing line and elongate in the length direction of the base film layer; And

And a power line formed at both sides of the heating material to supply power for heat generation of the heating material by contacting the heating material.
A leak detection device having a heat generating function according to another feature of the present invention,
A base film layer formed in the form of a tape;
A plurality of sensing lines formed long in a longitudinal direction on an upper surface of the base film layer;
A heating material formed on an upper surface of the base film layer and extending in a length direction of the base film layer with a predetermined width between the plurality of sensing lines; And
It consists of; a power line that is formed long on both sides of the heating material to supply power for heating the heating material by contacting the heating material.
In this case, an insulating layer is formed on the upper side of the heating material and the power line, and the heating material is preferably formed of either graphene or ruthenium.

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As described above, the present invention has the advantage of detecting a leakage as well as preventing freezing of a pipe by heating so that the freezing state can be sufficiently released by the heating material.

1 is a view showing the structure of a leak detection device having a conventional heating function.
Figure 2 is a view showing the structure of a leakage detection device having a heat generating function according to the present invention.
Figure 3 is a view showing the combined cross-section of Figure 2;
Fig. 4 is a diagram showing the structure of a leakage detecting device in which an outer protective layer is formed.

It will be described in detail below with reference to the accompanying drawings.

2 is a diagram showing the decomposition structure of the present invention, the base film layer 100 is formed in the form of a tape by a PI or PO or PTEF film, etc., and the base film layer 100 does not undergo thermal deformation even at high temperatures. It is formed of heat-resistant material that is not.

A pair of sensing lines 110, 120, 160, 170 are formed in a strip shape on both sides of the upper surface of the base film layer 100 in the longitudinal direction, and these sensing lines 110, 120, 160, 170 are made of silver compound or conductive It is formed in a printing method by ink.

As a printing method for forming the sensing lines 110, 120, 160, 170, gravure printing, roll to roll printing, and slot die coating may be used.

Between the sensing lines 110, 120, 160, 170, a heating material 150 is formed to be elongated in the longitudinal direction for heat generation, and this heating material 150 is graphene or ruthenium that generates heat by power. Various heating materials such as may be used.

In the case of forming the heating material with graphene, gravure printing, roll-to-roll printing, slot die coating, etc. may be used in the same manner as the method of printing the sensing lines 110, 120, 160, and 170.

In addition, power lines 130 and 140 are formed on both sides of the heating material 150 in the longitudinal direction. These power lines 130 and 140 are spaced apart from the sensing lines 110 and 120 and 160 and 170 and are separated from the heating material 150. It will have a touched state.

These power lines 130 and 140 may also be formed by gravure printing, roll-to-roll printing, slot die coating, or the like. In this case, a portion in contact with the heating material 150 as shown in FIG. 3 in order to increase the contact force with the heating material 150 is It is formed to extend further to the upper surface of the heating material 150, the power line (130, 140) and the upper side of the heating material 150, an insulating layer 180 for insulation is further formed.

The insulating layer 180 may be formed by being coated with a synthetic resin material or heat-resistant silicon.

Meanwhile, copper thin plates 131 and 141 may be further attached to the upper surfaces of the power lines 130 and 140 to increase conductivity and supply a large current for heat generation.

The upper protective film layer 200 is further laminated on the upper surface of the base film layer 100 on which the sensing lines 110, 120, 160, 170, the power lines 130, 140, the heating material 150, and the insulating layer 180 are formed. In the upper protective film layer 200, sensing holes 210, 220, 260, and 270 are formed parallel to each other in the longitudinal direction at a position corresponding to the portion where the sensing lines 110, 120, 160, and 170 are formed.

Like the base film layer 100, the upper protective film layer 200 is also formed of a PI or PO or PTEF film.

In this case, an adhesive layer 400 may be further formed of an insulating material to adhere the base film layer 100 and the upper protective film layer 200, and the sensing holes 210, 220, 260 and 270 may also be formed in the adhesive layer 400. The hole must be formed in the same position as.

In addition, a lower layer 300 made of a thin metal plate or a metal mesh in the form of a plate is further attached to the lower surface of the base film layer 100, which is caused by the high heat generated from the heating material 150. It is to prevent heat deformation and to maintain the strength of the base film layer 100.

Meanwhile, the sensing line 110 and the sensing line 120, the sensing line 160 and the sensing line 170, and the power line 130 and the power line 140 are connected to the connector at the end of the base film layer 100. By being electrically connected to each other, sensing power is supplied from a remote controller to the sensing lines 110 and 170, respectively, and power for heat generation is also supplied to the power line 130 from the remote controller.

When the present invention is wrapped or attached in a spiral shape to the outside of a fluid pipe through which water, chemical solutions, and other toxic substances flow, the fluid inside the fluid pipe does not freeze by the heat of 100°C or higher generated from the heating material 150. , Even in the frozen state, thawing can occur quickly.

In addition, when the fluid pipe breaks or leaks due to other reasons, the leaked fluid flows through the sensing holes 210, 220, 260, and 270 as shown in FIG. 3, and the leaked fluid, that is, a conductive fluid. As a result, the sensing lines 110, 120, 160, and 170 are electrically connected to each other to change the resistance value, and a change in the resistance value can be detected by a remote controller to generate a leakage alarm.

In addition, referring to FIG. 4, for completeness of the product according to the present invention, an outer protective layer 500 is formed to cover the entire outer surface, that is, the upper surface, the lower surface, and both sides, with heat-resistant silicone or polyolefin, etc. The protective layer 500 is formed by coating, extrusion, or drawing, and in this case, a hole is formed in a portion corresponding to the sensing holes 210,220, 260,270 of the upper hobo film layer 200, so that the sensing lines 110,120 ( 160 and 170) are exposed to the outside of the upper surface.

Accordingly, the leaked fluid penetrates the holes of the outer protective layer 500, the upper protective film layer 200, and the adhesive layer 400 to reach the sensing lines 110, 120, 160 and 170.

100: base film layer
110,120,160,170: sensing line
130,140: power line
150: heating material
200: upper protective film layer
210,220,260,270: Sensing Hall
300: lower layer
400: adhesive layer
500: outer protective layer

Claims (13)

A base film layer formed in the form of a tape;
A sensing line formed long in a longitudinal direction on an upper surface of the base film layer;
A heating material formed on an upper surface of the base film layer to have a predetermined width at one side of the sensing line and elongate in the length direction of the base film layer;
A power line formed at both sides of the heating material to supply power for heat generation of the heating material by contacting the heating material;
An insulating layer formed above the heating material and the power line;
A thin metal plate or a metal mesh attached to the lower surface of the base film layer; And
An upper protective film layer laminated on the upper surface of the base film layer to cover the insulating layer and the sensing line
Including,
In the upper protective film layer, a plurality of sensing holes are formed in the longitudinal direction at a portion corresponding to the sensing line.
Leak detection device with heating function. A base film layer formed in the form of a tape;
A plurality of sensing lines formed long in a longitudinal direction on an upper surface of the base film layer;
A heating material formed on an upper surface of the base film layer to have a predetermined width between the plurality of sensing lines and elongate in the length direction of the base film layer;
A power line formed at both sides of the heating material to supply power for heat generation of the heating material by contacting the heating material;
An insulating layer formed above the heating material and the power line;
A thin metal plate or a metal mesh attached to the lower surface of the base film layer; And
An upper protective film layer laminated on the upper surface of the base film layer to cover the insulating layer and the sensing line
Including,
In the upper protective film layer, a plurality of sensing holes are formed in the longitudinal direction at a portion corresponding to the sensing line.
Containing, a leakage detection device having a heating function. delete The method according to claim 1 or 2,
The heating material is a leak detection device having a heating function, characterized in that formed of any one of graphene or ruthenium. The method according to claim 1 or 2,
One side of the power line is a leakage detecting device having a heat generating function, characterized in that configured to extend to and contact the upper surface of the heating material. The method according to claim 1 or 2,
The sensing line is a leak detection device having a heat generating function, characterized in that formed by a printing method of a silver compound or conductive ink. The method according to claim 1 or 2,
The power line is a leakage detection device having a heat generating function, characterized in that formed by a printing method of a silver compound or conductive ink. The method according to claim 1 or 2,
A leakage detecting device having a heat generating function, characterized in that a copper thin plate layer is further provided on the upper surface of the power line. delete delete The method according to claim 1 or 2,
An outer protective layer surrounding the outer surface of the leak detection device
Including more,
A leakage detecting device having a heat generating function, wherein a plurality of sensing holes are formed in a longitudinal direction in a portion corresponding to a sensing line in the outer protective layer. The method of claim 11,
The outer protective layer is formed of heat-resistant silicone or polyolefin, a leakage detecting device having a heat generating function. The method according to claim 1 or 2,
An outer protective layer surrounding the outer surface of the leak detection device
Including more,
A leakage detecting device having a heat generating function, wherein a sensing hole is formed in the outer protective layer at the same position as the sensing hole formed in the upper protective film layer.

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